Post on 04-Aug-2020
ASSESSMENT PROTOCOL -
ADULT OCCUPANT PROTECTION
Version 2.0
November 2019
Preface
Where text is contained within square brackets this
denotes that the procedure being discussed is currently
being trialled in ASEAN NCAP. Its incorporation in the
Test Protocol will be reviewed at a later date.
During the test preparation, vehicle manufacturers are
encouraged to liaise with the laboratory and to check that
they are satisfied with the way cars are set up for testing.
Where a manufacturer feels that a particular item should
be altered, they should ask the laboratory staff to make
any necessary changes. Manufacturers are forbidden
from making changes to any parameter that will
influence the test, such as dummy positioning, vehicle
setting, laboratory environment etc.
It is the responsibility of the test laboratory to ensure that
any requested changes satisfy the requirements of
ASEAN NCAP. Where a disagreement exists between
the laboratory and manufacturer, the ASEAN NCAP
secretariat should be informed immediately to pass final
judgement. Where the laboratory staff suspect that a
manufacturer has interfered with any of the setup, the
manufacturer's representatives should be warned that
they are not allowed to do so themselves. They should
also be informed that if another incident occurs, they will
be asked to leave the test site.
Where there is a recurrence of the problem, the
manufacturer’s representatives will be told to leave the
test site and the Secretariat should be immediately
informed. Any such incident may be reported by the
Secretariat to the manufacturer and the persons
concerned may not be allowed to attend further ASEAN
NCAP tests.
DISCLAIMER: ASEAN NCAP has taken all reasonable
care to ensure that the information published in this
protocol is accurate and reflects the technical decisions
taken by the organisation. In the unlikely event that this
protocol contains a typographical error or any other
inaccuracy, ASEAN NCAP reserves the right to make
corrections and determine the assessment and subsequent
result of the affected requirement(s).
In addition to the settings specified in this protocol, the
following information will be required from the
manufacturer of the car being tested in order to facilitate
the vehicle preparation. A vehicle handbook should be
provided to the test laboratory prior to the assessment.
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ASSESSMENT PROTOCOL – ADULT OCCUPANT
PROTECTION
Table of Contents
1 INTRODUCTION ........................................................ 2
2 METHOD OF ASSESSMENT ..................................... 2
3 OFFSET DEFORMABLE BARRIER FRONTAL
IMPACT ASSESSMENT ................................................ 4
4 SIDE BARRIER IMPACT ASSESSMENT ............... 20
5 HEAD PROTECTION TECHNOLOGY (HPT)
EVALUATION.............................................................. 26
6 CONCEPTS BEHIND THE ASSESSMENTS .......... 33
7 REFERENCES ........................................................... 41
APPENDIX I ................................................................. 43
2
NEW CAR ASSESSMENT PROGRAM FOR
SOUTHEAST ASIAN COUNTRIES
(ASEAN NCAP)
ASSESSMENT PROTOCOL – ADULT OCCUPANT
PROTECTION
1 INTRODUCTION
The ASEAN NCAP programme is designed to provide a
fair, meaningful and objective assessment of the impact
performance of cars and provide a mechanism to inform
consumers. This protocol is based upon those used by the
European New Car Assessment Programme for adult
occupant protection ratings. Individual documents are
released for the four main areas of assessment as follow:
Assessment Protocol – Adult Occupant Protection
Assessment Protocol – Child Occupant Protection
Assessment Protocol – Safety Assist
Assessment Protocol – Motorcyclist Safety
In addition to these four assessment protocols, a separate
document is provided describing the method and criteria
by which the overall safety rating is calculated on the
basis of the car performance in each of the above areas of
assessment.
2 METHOD OF ASSESSMENT
The starting point for the assessment of adult occupant
protection is the dummy response data of the frontal
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impact. Initially, each relevant body area is given a score
based on the measured dummy parameters. These scores
can be adjusted after the test based on supplementary
requirements. For example, consideration is given to
whether the original score should be adjusted to reflect
occupant kinematics or sensitivity to small changes in
contact location, which might influence the protection of
different sized occupants in different seating positions.
The assessment also considers the structural performance
of the car by taking account of such aspects as steering
wheel displacement, pedal movement, foot well
distortion and displacement of the A pillar. The
adjustments or modifiers, are based on both inspection
and geometrical considerations are applied to the body
area assessments to which they are most relevant.
For Adult Occupant Protection, the overall rating is
based on the driver data, unless part of the passenger
fared less well. It is stated that the judgement relates
primarily to the driver. The adjusted rating for the
different body regions is presented, in a visual format of
coloured segments within a human body outline for the
driver and passenger.
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2.1 Points Calculation
A sliding scale system of points scoring has been adopted
for the biomechanical assessments. This involves two
limits for each parameter, a more demanding limit
(higher performance), beyond which a maximum score is
obtained and a less demanding limit (lower
performance), below which no points are scored. For the
adult rating, the maximum score for each body region is
four points. Where a value falls between the two limits,
the score is calculated by linear interpolation.
2.1.1 Capping
For adult occupant protection, capping limits are
maintained for criteria related to critical body regions.
Exceeding a capping limit generally indicates
unacceptable high risk at injury. In all cases, this leads to
loss of all points related to the tests. Capping limits can
be equal to or higher than the lower performance limit,
depending on the test.
3 OFFSET DEFORMABLE BARRIER
FRONTAL IMPACT ASSESSMENT
3.1 Criteria and Limit Values
The basic assessment criteria, with the upper and lower
performance limits for each parameter, are summarised
below. Where multiple criteria exist for an individual
body region, the lowest scoring parameter is used to
determine the performance of that region. The lowest
scoring body region of driver or passenger is used to
determine the score. For frontal impact, capping is
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applied on the critical body regions: head, neck and
chest.
3.1.1 Head
3.1.1.1 Drivers with Steering Wheel Airbags and
Passengers
If a steering wheel airbag is fitted the following criteria
are used to assess the protection of the head for the
driver. These criteria are always used for the passenger.
Note: HIC15 levels above 1000 have been recorded with
airbags, where there is no hard contact and no
established risk of internal head injury. A hard contact is
assumed, if the peak resultant head acceleration exceeds
80g, or if there is other evidence of hard contact.
If there is no hard contact, a score of 4 points is awarded.
If there is hard contact, the following limits are used:
Higher performance limit HIC15 500
Resultant Acc. 3 msec exceedence 72g
Lower performance limit and capping limit HIC15 700 (20% risk of injury ≥
AIS3 [1,2])
Resultant Acc. 3 msec exceedence 80g
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3.1.1.2 Drivers with No Steering Wheel Airbag
If no steering wheel airbag is fitted, and the following
requirements are met in the frontal impact test: HIC15 <700
Resultant Acc. 3 msec exceedence <80g
then 6.8kg spherical headform test specified in ECE
Regulation 12 [3] are carried out on the steering wheel.
The tester attempts to choose the most aggressive sites to
test and it is expected that two tests will be required, one
aimed at the hub and spoke junction and one at the rim
and spoke junction. The assessment is then based on the
following criteria:
Higher performance limit Resultant peak Acc. 80g
Resultant Acc. 3 msec exceedence 65g
Lower performance limit and capping limit HIC15 700
Resultant peak Acc. 120g
Resultant Acc. 3 msec exceedence 80g
From the spherical headform tests, a maximum of 2
points are awarded for performance better than the higher
limits. For values worse than the lower performance
limit, no points are awarded. For results between the
limits, the score is generated by linear interpolation. The
results from the worst performing test are used for the
assessment. This means that for cars, not equipped with a
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steering wheel airbag, the maximum score obtainable for
the driver’s head is 2 points.
3.1.2 Neck
Higher performance limit Shear 1.9kN @ 0 msec, 1.2kN @ 25 - 35msec, 1.1kN @
45msec
Tension 2.7kN @ 0 msec, 2.3kN @ 35msec, 1.1kN @
60msec Extension 42Nm
Lower performance limit and capping limit Shear 3.1kN @ 0msec, 1.5kN @ 25 - 35msec, 1.1kN @
45msec*
Tension 3.3kN @ 0msec, 2.9kN @ 35msec,1.1kN @
60msec*
Extension 57Nm*
(Significant risk of injury (*EEVC Limits)
Note: Neck Shear and Tension are assessed from
cumulative exceedence plots, with the limits being
functions of time. By interpolation, a plot of points
against time is computed. The minimum point on this plot
gives the score. Plots of the limits and colour rating
boundaries are given in Appendix I.
3.1.3 Chest
Higher performance limit Compression 22mm (5% risk of injury AIS3 [5])
Viscous Criterion 0.5m/sec (5% risk of injury AIS4)
Lower performance limit and capping limit
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Compression 42mm
Viscous Criterion 1.0m/sec (25% risk of injury AIS4)
3.1.4 Knee, Femur and Pelvis
Higher performance limit Femur compression 3.8kN(5% risk of pelvis injury [6])
Knee slider compressive displacement 6mm
Lower performance limit Femur Compression 9.07kN @ 0msec,
7.56kN @ 10msec* (Femur fracture limit [4])
Knee slider compressive displacement 15mm* (Cruciate
ligament failure limit [4,7])
(*EEVC Limit)
Note: Femur compression is assessed from a cumulative
exceedence plot, with the limits being functions of time.
By interpolation, a plot of points against time is
computed. The minimum point on this plot gives the
score. Plots of the limits and colour rating boundaries
are given in Appendix I.
3.1.5 Lower Leg
Higher performance limit Tibia Index 0.4
Tibia Compression 2kN
Lower performance limit Tibia Index 1.3*
Tibia Compression 8kN* (10% risk of fracture [4,8])
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3.1.6 Foot/Ankle
Higher performance limit Pedal rearward displacement 100mm
Lower performance limit Pedal rearward displacement 200mm
Notes:
1. Pedal displacement is measured for all pedals with no
load applied to them.
2. If any of the pedals are designed to completely release
from their mountings during the impact, no account is
taken of the pedal displacement provided that release
occurred in the test and that the pedal retains no
significant resistance to movement.
3. If a mechanism is present to move the pedal forwards
in an impact, the resulting position of the pedal is used in
the assessment.
4. The passenger’s foot/ankle protection is not currently
assessed.
3.2 Modifiers
3.2.1 Driver
The score generated from driver dummy data may be
modified where the protection for different sized
occupants or occupants in different seating positions, or
accidents of slightly different severity, can be expected to
be worse than that indicated by the dummy readings or
deformation data alone. In any single body region, the
score may reduce by up to a maximum of two points.
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The concepts behind the modifiers are explained in
Section 0.
3.2.1.1 Head
Unstable Contact on the Airbag
If during the forward movement of the head its centre of
gravity moves further than the outside edge of the airbag,
head contact is deemed to be unstable. The score is
reduced by one point. If for any other reason head
protection by the airbag is compromised, such as by
detachment of the steering wheel from the column, or
bottoming-out of the airbag by the dummy head, the
modifier is also applied.
Note: Head bottoming-out is defined as follows: There is
a definite rapid increase in the slope of one or more of
the head acceleration traces, at a time when the dummy
head is deep within the airbag. The acceleration spike
associated with the bottoming out should last for more
than 3ms.The acceleration spike associated with the
bottoming out should generate a peak value more than 5
g above the likely level to have been reached if the spike
had not occurred. This level will be established by
smooth extrapolation of the curve between the start and
end of the bottoming out spike.
Hazardous Airbag Deployment
If, within the head zone, the airbag unfolds in a manner
in which a flap develops, which sweeps across the face of
an occupant vertically or horizontally the -1 point
modifier for unstable airbag contact will be applied to the
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head score. If the airbag material deploys rearward,
within the “head zone” at more than 90 m/s, the -1 point
modifier will be applied to the head score.
Incorrect Airbag Deployment
Any airbag(s) which does not deploy fully in the
designed manner will attract a -1 point modifier
applicable to each of the most relevant body part(s) for
the affected occupant. For example, where a steering
wheel mounted airbag is deemed to have deployed
incorrectly, the penalty will be applied to the frontal
impact driver’s head (-1). Where, a passenger knee
airbag fails to deploy correctly, the penalty will be
applied to the frontal impact passenger left and right
knee, femur and pelvis (-1).
Where the incorrect deployment affects multiple body
parts, the modifier will be applied to each individual
body part. For example, where a seat or door mounted
side airbag, that is intended to provide protection to the
head as well as the thorax, abdomen or pelvis deploys
incorrectly, the penalty will be applied to two body
regions, -1 to the head and -1 to the chest.
The modifier(s) will be applied to the scores of the
impacts for which the airbag was intended to offer
protection, regardless of the impact in which it deployed
incorrectly. For example, the penalty will be applied to
the side and pole impact scores if a side protection airbag
deploys incorrectly during the frontal crash. Or, if a knee
airbag deploys incorrectly in the full width impact, the
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modifier will be applied to the pelvic region of both the
offset and full width tests. Where any frontal protection
airbag deploys incorrectly, ASEAN NCAP will not
accept knee mapping data for that occupant.
Unstable Contact on a Steering Wheel without an Air
Bag
If, during the forward movement of the head, its centre of
gravity moves radially outwards further than the outside
edge of the steering wheel rim, head contact is deemed to
be unstable. The score is reduced by one point. If for any
other reason head contact on the steering wheel is
unstable, such as detachment of the steering wheel from
the column, the modifier is also applied.
Displacement of the Steering Column
The score is reduced for excessive rearward, lateral or
upward static displacement of the top end of the steering
column. Up to 90 percent of the EEVC limits, there is no
penalty. Beyond 110 percent of the EEVC limits, there is
a penalty of one point. Between these limits, the penalty
is generated by linear interpolation. The EEVC
recommended limits are: 100mm rearwards, 80mm
upwards and 100mm lateral movement. The modifier
used in the assessment is based on the worst of the
rearward, lateral and upward penalties.
3.2.1.2 Chest
Displacement of the A Pillar
The score is reduced for excessive rearward displacement
of the driver’s front door pillar, at a height of 100mm
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below the lowest level of the side window aperture. Up
to 100mm displacement there is no penalty. Above
200mm there is a penalty of two points. Between these
limits, the penalty is generated by linear interpolation.
Integrity of the Passenger Compartment
Where the structural integrity of the passenger
compartment is deemed to have been compromised, a
penalty of one point is applied. The loss of structural
integrity may be indicated by characteristics such as:
• Door latch or hinge failure, unless the door is
adequately retained by the door frame.
• Buckling or other failure of the door resulting in
severe loss of fore/aft compressive strength.
• Separation or near separation of the cross facia
rail to A pillar joint.
• Severe loss of strength of the door aperture.
When this modifier is applied, knee mapping data will
not be accepted.
Steering Wheel Contact Where there is obvious direct loading of the chest from the steering wheel, a one-point penalty is applied.
Shoulder belt load (Driver and Front Passenger)
Where the shoulder belt load measured, exceeds 6kN a
two-point penalty is applied.
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3.2.1.3 Knee, Femur & Pelvis
Variable Contact
The position of the dummy’s knees is specified by the
test protocol. Consequently, their point of contact on the
facia is pre-determined. This is not the case with human
drivers, who may have their knees in a variety of
positions prior to impact. Different sized occupant and
those seated in different positions may also have different
knee contact locations on the facia and their knees may
penetrate into the facia to a greater extent. In order to
take some account of this, a larger area of potential knee
contact is considered. If contact at other points, within
this greater area, would be more aggressive penalties are
applied.
The area considered extends vertically 50mm above and
below the maximum height of the actual knee impact
location [8]. Vertically upwards, consideration is given to
the region up to 50mm above the maximum height of
knee contact in the test. If the steering column has risen
during the test it may be repositioned to its lowest setting
if possible. Horizontally, for the outboard leg, it extends
from the centre of the steering column to the end of the
facia. For the inboard leg, it extends from the centre of
the steering column the same distance inboard, unless
knee contact would be prevented by some structure such
as a centre console. Over the whole area, an additional
penetration depth of 20mm is considered, beyond that
identified as the maximum knee penetration in the test.
The region considered for each knee is generated
independently. Where, over these areas and this depth,
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femur loads greater that 3.8kN and/or knee slider
displacements greater than 6mm would be expected, a
one point penalty is applied to the relevant leg.
Concentrated Loading
The biomechanical tests, which provided the injury
tolerance data, were carried out using a padded impactor
which spread the load over the knee. Where there are
structures in the knee impact area which could
concentrate forces on part of the knee, a one point
penalty is applied to the relevant leg.
Where a manufacturer is able to show, by means of
acceptable test data, that the Variable Contact and/or
Concentrated Loading modifiers should not be applied,
the penalties may be removed.
If the Concentrated load modifier is not applied to any of
the driver's knees, the left and right knee zones (defined
above) will both be split into two further areas, a
‘column’ area and the rest of the facia. The column area
for each knee will extend 60mm from the centreline of
the steering column and the remainder of the facia will
form the other area for each knee. As a result, the one-
point penalty for Variable Contact will be divided into
two with one half of a point being applied to the column
area and one half of a point to the remainder of the facia
for each knee.
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3.2.1.4 Lower Leg
Upward Displacement of the Worst Performing Pedal
The score is reduced for excessive upward static
displacement of the pedals. Up to 90 percent of the limit
considered by EEVC, there is no penalty. Beyond 110
percent of the limit, there is a penalty of one point.
Between these limits, the penalty is generated by linear
interpolation. The limit agreed by EEVC was 80mm.
3.2.1.5 Foot & Ankle
Footwell Rupture
The score is reduced if there is significant rupture of the
footwell area. This is usually due to separation of spot-
welded seams. A one-point penalty is applied for
footwell rupture. The footwell rupture may either pose a
direct threat to the driver’s feet, or be sufficiently
extensive to threaten the stability of footwell response.
When this modifier is applied, knee mapping data will
not be accepted.
Pedal Blocking
Where the rearward displacement of a ‘blocked’ pedal
exceeds 175mm relative to the pre-test measurement, a
one-point penalty is applied to the driver’s foot and ankle
assessment. A pedal is blocked when the forward
movement of the intruded pedal under a load of 200N is
<25mm. Between 50mm and 175mm of rearward
displacement the penalty is calculated using a sliding
scale between 0 to 1 point.
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3.2.2 Passenger
The score generated from passenger dummy data may be
modified where the protection for different sized
occupants or occupants in different seating positions, or
accidents of slightly different severity, can be expected to
be worse than that indicated by the dummy readings
alone. In any single body region, the score may reduce by
up to a maximum of two points. The concepts behind the
modifiers are explained in section 0. The modifiers
applicable to the passenger are:
• Unstable Contact on the airbag
• Hazardous airbag deployment
• Shoulder load belt
• Incorrect airbag deployment
• Knee, Femur & Pelvis, Variable Contact
• Knee, Femur & Pelvis, Concentrated loading
The assessments airbag stability, head bottoming-out
(where present) and the knee impact areas are the same
as for driver. For the outboard knee, the lateral range of
the knee impact area extends from the centre line of the
passenger seat to the outboard end of the facia. For the
inboard knee, the area extends the same distance inboard
of the seat centre line, unless knee contact is prevented
by the presence of some structure such as the centre
console. The passenger knee zones and penalties will not
be divided into two areas even if the concentrated load
modifier is not applied.
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3.2.3 Door Opening during the Impact
When a door opens in the test, a minus one-point
modifier will be applied to the score for that test. The
modifier will be applied to the frontal impact assessment
for every door (including tailgates and moveable roofs)
that opens. The number of door opening modifiers that
can be applied to the vehicle score is not limited.
3.2.4 Door Opening Forces after the Impact
The force required to unlatch and open each side door to
an angle of 45 degrees is measured after the impact. A
record is also made of any doors which unlatch or open
in the impact. Currently, this information is not used in
the assessment but it may be referred to in the text of the
published reports.
Door opening forces are categorised as follows:
Opens normally Normal hand force is sufficient
Limited force 100N
Moderate force > 100N to < 500N
Extreme hand force 500N
Tools had to be used Tools necessary
3.3 Scoring & Visualization
The protection provided for adults for each body region
are presented visually, using coloured segments within
body outlines. The colour used is based on the points
awarded for that body region (rounded to three decimal
places), as follows:
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Green 4.000 points
Yellow 2.670 - 3.999 points
Orange 1.330 - 2.669 points
Brown 0.001 - 1.329 points
Red 0.000 points
For frontal impact, the body regions are grouped
together, with the score for the grouped body region
being that of the worst performing region or limb.
Results are shown separately for driver and passenger.
The grouped regions are:
• Head and Neck,
• Chest,
• Knee, Femur, Pelvis (i.e. left and right femur and knee
slider)
• Leg and Foot (i.e. left and right lower leg and foot and
ankle).
This assessment will be applied on the basis of dummy
response alone, for any body region where there is an
unacceptably high risk of life-threatening injury i.e.
the dummy response has exceeded the lower
performance limit. The body regions which could give
rise to a ‘star cap’ are the head, neck and chest.
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4 SIDE BARRIER IMPACT ASSESSMENT
4.1 Criteria and Limit Values
The basic assessment criteria used for side barrier
impact, with the upper and lower performance limits for
each parameter, are summarized below. The assessments
are divided into four individual body regions, the head,
chest, abdomen and pelvis. A maximum of four points
are available for each body region. Where multiple
criteria exist for an individual body region, the lowest
scoring parameter is used to determine the performance
of that region. There is no limit to the number of
modifiers that can be applied. The concepts behind the
modifiers are explained in section 6.
Note: The requirement is for the fitment of a head
protection system, meaning that the manufacturer is free
to use a solution other than an airbag. However, for
technologies other than conventional curtain or head
airbags, the manufacturer is requested to provide
evidence that the system is effective, at least in principle,
before a test can be allowed.
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4.1.1 Head
Higher performance limit
HIC
36
650 (5% risk of injury ≥
AIS3 [1,2])
Resultant Acc. 3 msec
exceedence 72g
Lower performance limit
HIC
36 1000
(20% risk of injury ≥
AIS3 [1,2])
Resultant Acc. 3 msec
exceedence 88g
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4.1.2 Chest
The assessment is based on the worst performing
individual rib.
Higher performance limit
Compression
Viscous Criterion
22mm
0.32
(5% risk of injury
≥AIS3)
(5% risk of injury
≥AIS3)
Lower performance limit
Compression
Viscous Criterion
42mm
1.0
(30% risk of
injury≥AIS3)
(50% risk of
injury≥AIS3)
4.1.3 Abdomen
Higher performance limit
Total Abdominal Force 1.0 kN
Lower performance limit
Total Abdominal Force 2.5 kN (* EEVC Limit)
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4.1.4 Pelvis
Higher performance limit
Pubic Symphysis Force 3.0kN
Lower performance limit
Pubic Symphysis Force 6.0kN*
(Pelvic Fracture in
Young Adults)
(*EEVC Limit)
4.2 Modifiers
4.2.1 Incorrect Airbag Deployment
Any airbag(s) which does not deploy fully in the
designed manner will attract a -1 point modifier
applicable to each of the most relevant body part(s) for
the affected occupant. For example, where a head curtain
airbag is deemed to have deployed incorrectly, the
penalty will be applied to the side impact driver’s head (-
1). Where the incorrect deployment affects multiple body
parts, the modifier will be applied to each individual
body part. For example, where a seat or door mounted
side airbag fails to deploy correctly that is intended to
provide protection to the head as well as the thorax,
abdomen and pelvis, the penalty will be applied to two
body regions, the head (-1) and the chest (-1). The two
penalties would also be applicable to both the side and
pole impacts, which are scaled down in the final vehicle
rating.
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The modifier will be applied even if the airbag was not
intended to offer protection in that particular impact. For
example, the penalty will be applied if a driver’s knee
airbag deploys incorrectly in a side or pole impact. In this
case the modifier will be applied to both frontal impact
driver knee, femur and pelvis body parts. Where a frontal
protection airbag deploys incorrectly, knee-mapping is
not permitted for the occupant whom the airbag was
designed to protect.
4.2.2 Backplate Loading
Where the backplate load Fy exceeds 4.0kN, a two-point
penalty is applied to the driver’s chest assessment.
Between 1.0kN and 4.0kN the penalty is calculated using
a sliding scale from 0 to 2 points. Only loads applied to
the backplate, which might unload the chest by
accelerating the spine away from the intruding side are
counted.
Higher performance limit
Fy 1.0kN
Lower performance limit
Fy 4.0kN
4.2.3 T12 Modifier
Where the T12 loads Fy and Mx exceed 2.0kN or 200Nm
respectively, a two-point penalty is applied to the driver’s
chest assessment. Between 1.5kN – 2.0kN or 150Nm –
200Nm the penalty is calculated using a sliding scale
from 0 to 2 points. The assessment is based upon the
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worst performing parameter. Only loads which are
transmitted up the spine, which might unload the chest
during the loading phase of the impact, will be
considered.
Higher performance limit
Fy 1.5kN ; Mx 150Nm
Lower performance limit
Fy 2.0kN ; Mx 200Nm
Using SAE J211 sign convention
Fy > 0 and Mx < 0 for LHD vehicles
Fy < 0 and Mx > 0 for RHD vehicles
4.2.4 Door Opening during the Impact
When a door opens in the test, a minus one-point
modifier will be applied to the score for that test. The
modifier will be applied to the side impact assessment
score for every door (including tailgates and moveable
roofs) that opens. The number of door opening modifiers
that can be applied to the vehicle score is not limited.
4.2.5 Door Opening Forces after the Impact
A check is made to ensure that the doors on the non-
struck side can be opened. The doors on the struck side
are not opened.
4.3 Scoring & Visualization
The protection provided for adults for each body region
are presented visually, using coloured segments within
26
body outlines. The colour used is based on the points
awarded for that body region (rounded to three decimal
places), as follows:
Green ‘Good’ 4.000 points
Yellow ‘Adequate’ 2.670 - 3.999 points
Orange ‘Marginal’ 1.330 - 2.669 points
Brown ‘Weak’ 0.001 - 1.329 points
Red ‘Poor’ 0.000 points
5 HEAD PROTECTION TECHNOLOGY (HPT)
EVALUATION
Vehicles equipped with head protection side airbags,
curtain, seat mounted or any other, will have the inflated
energy absorbing areas evaluated by means of a
geometric assessment. The airbags must provide
protection for a range of occupant size seated at the front
on both sides of the vehicle. Where a vehicle does offer
sufficient protection, maximum 8 point will be awarded
based on ASEAN NCAP Fitment Rating System Version
1.1 (FRS).
5.1 Coverage Areas
To ensure adequate head protection is offered, the head
protection device coverage is assessed in the geometric
area, or the Head Protection Device (HPD) assessment
zone, where the occupant head would most likely impact
side structures. If the vehicle is equipped with movable
rear seats the seat shall be set to the most rearward
position. If there is a third row of fixed seats, these will
be included in the assessment unless they are per
27
manufacturers’ recommendation as unsuitable for adult
occupation (handbook).
5.2 Application
Where the airbags differ between the left- and right-hand
sides of the vehicle, the airbags on both sides of the
vehicle will be evaluated and the assessment will be
based upon worst performing side. All areas of the
airbag, both front and rear, will be evaluated and the
assessment will be based upon the worst performing part
of any of the airbags.
5.3 Exclusion
The head protecting airbags should cover all glazed areas
within the defined zone up to the edge of door daylight
opening (FMVSS201) where it meets the roofline, B-
pillar, C-pillar and door waistline. Seams in the airbag
will not be penalised provided that the un-inflated area is
no wider than 15mm. Any other areas where the airbag
layers are connected will not be penalised provided that
the surrounding areas are inflated and any un-inflated
areas are no larger than 50mm in diameter or equivalent
area or the sum of the major and minor axes of individual
areas does not exceed 100mm. In the case that the un-
inflated area would be larger than described above, the
OEM shall provide data to demonstrate sufficient energy
absorption is guaranteed.
Where a vehicle is fitted with a third row of foldable or
removable seats, the third row (only) will be excluded
from the assessment.
28
5.4 HPT Assessment
Head Protection Technology (HPT) can be other than an
airbag, as long as it protects the head. However, for
technologies other than the conventional curtain or head
airbags, manufacturer is requested to provide evidence
that the system is effective, at least in principle, before an
assessment can be carried out.
In order to demonstrate the functionality and
performance of the HPT and qualify for further
assessment on Fitment Rating System (FRS), ASEAN
NCAP will accept any of the following options;
a. Assessment by ASEAN NCAP. This will be
performed after the ASEAN NCAP side barrier impact
test. If the vehicle model is not equipped with the HPT
(for example, only available in higher variant), the
manufacturer is responsible to provide the vehicle model
with the HPT to ASEAN NCAP for further assessment
without crash testing, OR
b. Another ASEAN NCAP side barrier impact test is
performed with vehicle model with HPT (if the tested
model is not equipped with HPT) and assessment by
ASEAN NCAP, OR
c. Assessment by manufacturer and submission of in-
house test report.
The deployment situation of the SCA shall be recorded
and confirmed as follows. The results of deployment of
29
the SCA confirmed on the struck side shall be deemed to
represent those on the opposite side (if ASEAN NCAP
side barrier impact testing is conducted for this model).
However, when the struck side is deemed unable to
represent the opposite side due to differences in structure,
installation location, etc., the method of confirmation
shall be determined upon consultation between the
ASEAN NCAP and the manufacturer.
The deployment of the SCA shall be confirmed based on
the analysis of high-speed videos:
i. The SCA deployed on the outer side of the
dummy’s head.
ii. The SCA smoothly deployed without scratches or
breakage during deployment.
iii. The dummy’s head was protected by the energy-
absorbing effective area of the SCA.
5.4.1 Front Seat
a. The front edge of the energy-absorbing area of the
SCA projected on the centre plane of the vehicle shall be
forward of the base front edge line (hereinafter referred
to as the “base front edge”; the concept is shown in
Figure X) which is drawn from a point 200 mm
horizontally forward from the centre of gravity of the
dummy’s head projected on the centre plane of the
vehicle to a point 160 mm downward or to the bottom
line of the windshield.
b. Provided, however, it is not necessary to meet this
requirement if the front edge of the energy-absorbing
30
area of the SCA is above the upper level of an adjacent
window glass. In this case, the front edge of the deployed
SCA shall be confirmed as follows. Before conducting
the test, the centre of gravity of the dummy’s head and
the base front edge shall be marked on the test vehicle
body in an area which would not be deformed upon
collision, then after the test, the SCA shall be filled with
a volume of compressed air necessary to deploy it to the
size of complete deployment, and it shall be confirmed
that the airbag front edge line is forward of the base front
edge line. If the right and left SCAs are symmetrical, the
opposite side SCA may be used for confirmation.
Figure 1: The area considered for SCA evaluation
31
5.4.2 Rear Seat
a) Using the location of the H-point for the rear
seating position as per EURO NCAP Rear Whiplash
protocol, calculate and record the corresponding head
centre of gravity positions in the most forward and
rearward seating positions:
5th female Head CoG in most forward seating position:
XCoG,5th = H-point(X) + 126 - seat travel (if applicable)
ZCoG,5th = H-point(Z) + 594
95th male Head CoG in most rearward seating position:
XCoG,95th = H-point(X) + 147
ZCoG,95th = H-point(Z) + 693
Figure 2: Area considered for SCA evaluation for Rear
Seat
A B
C D
Fixed Rear Bench Moveable Rear Bench
32
The four corners of the Head CoG-box are:
X-position Z-position
A XCoG,5th ZCoG,95th
B XCoG,95th ZCoG,95th
C XCoG,95th ZCoG,5th
D XCoG,5th ZCoG,5th
b) The head protection device (HPD) evaluation
zone is defined as a rounded rectangle around the head
CoG box at a distance of 82mm from the upper and
fore/aft edges and 52mm below the bottom edge. It is
acceptable for the 82mm radius in the lower corners of
the airbag to be cut-off at 52mm below the CoG box.
c) The zone shall be constructed parallel and
perpendicular to the ground reference level
.
33
d) Mark the vertical lines X5 and X95 and the
horizontal lines Z95 and Z5 on both the vehicle interior
at the struck side and on the vehicle exterior on the non-
struck side.
5.5 Prerequisites
Beginning 1 January 2023, UN R135 are required as
prerequisites for HPT assessment. In-house results are
acceptable.
6 CONCEPTS BEHIND THE ASSESSMENTS
34
6.1 Frontal Impact
6.1.1 Head
CONCEPT: The driver's head should be predictably
restrained by the airbag, and should remain protected by
the airbag during the dummy's forward movement. There
should be no bottoming out of the airbag.
CONCEPT: Hazardous airbag deployment
The deployment mode of the airbag should not pose a
risk of facial injury to occupants of any size.
CONCEPT: Incorrect airbag deployment
All airbags that deploy during an impact should do so
fully and in the designed manner so as to provide the
maximum amount of protection to occupants available. It
is expected that, where required, all airbags should
deploy in a robust manner regardless of the impact
scenario.
CONCEPT: Geometric control of steering wheel
movement is needed to ensure that the airbag launch
platform remains as close as possible to the design
position, to protect a full range of occupant sizes.
6.1.2 Neck
35
CONCEPT: Neck injuries are frequent, but relatively
little is known about appropriate injury criteria. The
neck criteria recommended by EEVC are used to identify
poorly designed restraint systems. It is not expected that
many cars will fail these requirements.
In addition to the EEVC recommended limits, additional
ones have been added, at the request of the car
manufacturers. It is assumed that good restraint systems
will have no problems meeting these criteria.
6.1.3 Chest
CONCEPT: Rib compression is used as the main guide
to injury risk. It is expected that the Viscous Criterion
will only identify cars with poorly performing restraint
systems.
The injury risk data is relevant for seat belt only loading
rather than combined seat belt and airbag loading. No
change is made in the event of combined seat belt and
airbag restraint. This avoids value judgements about the
extent of airbag restraint on the chest and is in line with
the EEVC recommendation.
CONCEPT: There is an interrelationship between chest
loading, as measured by the above dummy criteria, and
intrusion. To ensure that a good balance is struck, a
geometric criterion on waist level intrusion, as measured
by door pillar movement at waist level, is used.
36
CONCEPT: When the passenger compartment becomes
unstable, any additional load can result in unpredictable
excessive further collapse of the passenger compartment.
When the passenger compartment becomes unstable the
repeatability of the car’s response in the test becomes
poor and confidence in the car’s performance is reduced.
CONCEPT: The chest performance criteria are
developed for loads applied by a seat belt. The more
concentrated loading from a “stiff” steering wheel
exposes the chest to direct loading injury.
6.1.4 Abdomen
Protection of the abdomen is important, but no criteria or
assessment techniques are available at present.
6.1.5 Knee, Femur & Pelvis
CONCEPT: Transmitting loads through the knee joint
from the upper part of the tibia to the femur can lead to
cruciate ligament failure.
Zero knee slider displacement is both desirable and
possible. The higher performance limit allows for some
possible movement due to forces transmitted axially up
the tibia.
CONCEPT: The knee impact area should have
uniformly good properties over a wide area of potential
impact sites. This is to account for people sitting with
37
their knees in different positions and slight variations in
impact angle. The characteristics of the area should not
change markedly if knee penetration is slightly greater
than that observed with the 50th percentile dummy in this
test. This takes into account the protection of different
sized occupants or occupants in different seating
positions.
CONCEPT: Loading on the knee should be well
distributed and avoid concentration that could result in
localised damage to the knee.
The injury tolerance work that supports the legislative
femur criterion was conducted with padded impactors
that spread the load over the knee.
6.1.6 Lower Leg
CONCEPT: Loads resulting in fracture of the tibia
produce bending moments and forces measurable at the
upper and lower ends of the tibia. These measurements
on the tibia relate to risk of tibia fracture.
At the request of the car manufacturers, further limits
were added to those proposed for lower leg protection.
These limits can be expected to help protect the ankle
joint.
CONCEPT: Pedal blocking
There should be no blocking of any foot operated pedals
which have displaced rearward after the impact; blocked
38
pedals represent a greater hazard to the lower limbs of
the driver than non-blocked pedals.
6.1.7 Foot and Ankle
CONCEPT: Expert opinion suggests that a Tibia Index
of less than 0.2 would be necessary to prevent ankle joint
failure. Until a biofidelic ankle and foot become
available, the assessment will be based on intrusion.
Intrusion is highly correlated with the risk of injury.
CONCEPT: Rupture of the footwell exposes the
occupant to additional dangers. Objects outside the
passenger compartment may enter, parts of the occupant
may contact items outside the passenger compartment,
there is a risk from exposed edges and the structure may
become unstable.
6.2 Side Impact
CONCEPT: Incorrect airbag deployment All airbags that deploy during an impact should do so fully and in the designed manner so as to provide the maximum amount of protection to occupants available. It is expected that, where required, all airbags should deploy in a robust manner regardless of the impact scenario.
CONCEPT: Seat position in side impact Effective side impact protection needs to consider all sizes of occupants. This concept is included in the EU
39
Directive. Currently, side impact tests are conducted with the seat in the design position. In future, consideration may be given to the level of protection in other seating positions. 6.3 Door Opening
CONCEPT: The intention is to ensure that the structural
integrity is maintained. The underlying principle is to
minimise the risks of occupant ejection occurring.
The ‘door opening’ modifier will be applied if any of the
following have occurred:
the latch has fully released or shows significant partial
release, either by release of its components from one
another, or effective separation of one part of the latch
from its supporting structure
the latch has moved away from the fully latched
condition
if any hinge has released either from the door or
bodyshell or due to internal hinge failure
if there is a loss of structure between the hinges and
latches
if door or hinges fail whilst the door opening tests are
being conducted post impact, as loading from an
occupant could have a similar effect.
40
if there was any potential risk of occupant ejection and/or
partial ejection/entrapment from openings such as sliding
doors or moveable roofs. Dynamic opening during the
impact of any apertures, such as roofs, will also be
considered even if the openings have closed post test.
if both side doors latch together with no b-pillar or other
form of restraint, the modifier may apply to both the
front and rear doors.
41
7 REFERENCES
Prasad, P. and H. Mertz. The position of the US delegation to the ISO Working Group 6 on the use of HIC in the automotive environment. SAE Paper 851246. 1985
Mertz, H., P. Prasad and G. Nusholtz. Head Injury Risk
Assessment for forehead impacts. SAE paper 960099
(also ISO WG6 document N447)
ECE Regulation 12 Revision 3 - Uniform Provisions Concerning the Approval of Vehicles With Regard To the Protection of the Driver against the Steering Mechanism in the Event of Impact. 1994.
Mertz, H. Anthropomorphic test devices. Accidental Injury - Biomechanics and Prevention, Chapter 4. Ed. Alan Nahum and John Melvin. Pub. Springer-Verlag 1993.
Mertz, H., J. Horsch, G. Horn and R Lowne. Hybrid III sternal deflection associated with thoracic injury severities on occupants restrained with force-limiting shoulder belts. SAE paper 910812. 1991.
Wall, J., R. Lowne and J. Harris. The determination of tolerable loadings for car occupants in impacts. Proc 6th ESV Conference. 1976
Viano, D., C. Culver, R. Haut, J. Melvin, M. Bender, R. Culver and R. Levine. Bolster impacts to the knee and
42
tibia of human cadavers and an anthropomorphic dummy. SAE Paper 780896, Proc 22nd Stapp conference.
EEVC WG. The Validation of the EEVC Frontal Impact Test Procedure. Proc 15th ESV Conference, Melbourne, 1996.
Schneider, L.W., Vogel, M. and Bosio, C.A. Locations of driver knees relative to knee bolster design. The University of Michigan Transportation Research Institute, Ann Arbor, Michigan. UMTRI-88-40. September 1988.
Lowne, R. and E. Janssen. Thorax injury probability estimation using production prototype EUROSID. ISO/TC22/SC12/WG6 document N302.
43
APPENDIX I
GRAPHICAL LIMITS FOR CUMULATIVE
EXCEEDENCE PARAMETERS
1 Upper Neck Shear FX - Positive
2 Upper Neck Shear FX - Negative
3 Upper Neck Tension FZ
4 Femur Compression
44
0 5 10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85
Time - ms
-1
0
1
2
3
4
5
Exce
eden
ce V
alue:
Upper
Nec
k F
X -
kN
Cumulative Exceedence Limits
Filtered at CFC_1000
Positive Cumulative Exceedence Time
RedBrownOrangeYellowGreen
0 5 10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85
Time - ms
-5
-4
-3
-2
-1
0
1
Exce
eden
ce V
alue:
Upper
Nec
k F
X -
kN
Cumulative Exceedence Limits
Filtered at CFC_1000
Negative Cumulative Exceedence Time
RedBrownOrangeYellowGreen
45
0 5 10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85
Time - ms
-1
0
1
2
3
4
5
Exce
ednec
e V
alue:
Upper
Nec
k F
Z -
kN
Cumulative Exceedence Limits
Filtered at CFC_1000
Positive Cumulative Exceedence Time
Processed
on 29.01.2002
RedBrownOrangeYellowGreen
0 5 10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85
Time - ms
-12
-10
-8
-6
-4
-2
0
2
Exce
eden
ce V
alue:
Fem
ur
- kN
Cumulative Exceedence Limits
Filtered at CFC_600
Negative Cumulative Exceedence Time
Processed
on 01.02.2002
Red
Brown
Orange
Yellow
Green
46
Editors Yahaya Ahmad Malaysian Institute of Road Safety Research (MIROS) Ir. Dr. Khairil Anwar Abu Kassim (Adjunct. Prof) Malaysian Institute of Road Safety Research (MIROS) Mohd Hafiz Johari Malaysian Institute of Road Safety Research (MIROS) Salina Mustaffa Malaysian Institute of Road Safety Research (MIROS) Zulhaidi Mohd Jawi Malaysian Institute of Road Safety Research (MIROS) Ir. Adrianto Sugiarto Wiyono Politeknik APP Dr. Annisa Jusof Institut Teknologi Bandung (ITB) Dr. Ir. Sigit P. Santosa Institut Teknologi Bandung (ITB) Dr. Atsuhiro Konosu Japan Automobile Research Institute (JARI) Ahmed Ismail Hj. Amin Automobile Association of Malaysia (AAM) Dr. Mohd Radzi Abu Mansor Universiti Kebangsaan Malaysia (UKM) Assoc. Prof. Dr. Wira Jazair Universiti Teknologi Malaysia (UTM) Assoc. Prof. Dr. Julaluk Carmai The Sirindhorn International Thai German Graduate School of Engineering (TGGS)
47
Assoc. Prof. Dr. Saiprasit Koetniyom The Sirindhorn International Thai German Graduate School of Engineering (TGGS) Assoc. Prof. Dr. Ly Hung Anh Ho Chi Minh City University of Technology (HCMUT) Dr. Siti Zaharah Ishak Malaysian Institute of Road Safety Research (MIROS)
48